<?php

namespace PHPExcel\Calculation;

/**
 * EULER
 */
define('EULER', 2.71828182845904523536);

/**
 * PHPExcel_Calculation_Engineering
 *
 * Copyright (c) 2006 - 2015 PHPExcel
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 *
 * @category PHPExcel
 * @package PHPExcel_Calculation
 * @copyright Copyright (c) 2006 - 2015 PHPExcel (http://www.codeplex.com/PHPExcel)
 * @license http://www.gnu.org/licenses/old-licenses/lgpl-2.1.txt LGPL
 * @version ##VERSION##, ##DATE##
 */
class Engineering {
    /**
     * Details of the Units of measure that can be used in CONVERTUOM()
     *
     * @var mixed[]
     */
    private static $conversionUnits = array(
    'g' => array(
    'Group' => 'Mass',
    'Unit Name' => 'Gram',
    'AllowPrefix' => true 
    ),
    'sg' => array(
    'Group' => 'Mass',
    'Unit Name' => 'Slug',
    'AllowPrefix' => false 
    ),
    'lbm' => array(
    'Group' => 'Mass',
    'Unit Name' => 'Pound mass (avoirdupois)',
    'AllowPrefix' => false 
    ),
    'u' => array(
    'Group' => 'Mass',
    'Unit Name' => 'U (atomic mass unit)',
    'AllowPrefix' => true 
    ),
    'ozm' => array(
    'Group' => 'Mass',
    'Unit Name' => 'Ounce mass (avoirdupois)',
    'AllowPrefix' => false 
    ),
    'm' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Meter',
    'AllowPrefix' => true 
    ),
    'mi' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Statute mile',
    'AllowPrefix' => false 
    ),
    'Nmi' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Nautical mile',
    'AllowPrefix' => false 
    ),
    'in' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Inch',
    'AllowPrefix' => false 
    ),
    'ft' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Foot',
    'AllowPrefix' => false 
    ),
    'yd' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Yard',
    'AllowPrefix' => false 
    ),
    'ang' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Angstrom',
    'AllowPrefix' => true 
    ),
    'Pica' => array(
    'Group' => 'Distance',
    'Unit Name' => 'Pica (1/72 in)',
    'AllowPrefix' => false 
    ),
    'yr' => array(
    'Group' => 'Time',
    'Unit Name' => 'Year',
    'AllowPrefix' => false 
    ),
    'day' => array(
    'Group' => 'Time',
    'Unit Name' => 'Day',
    'AllowPrefix' => false 
    ),
    'hr' => array(
    'Group' => 'Time',
    'Unit Name' => 'Hour',
    'AllowPrefix' => false 
    ),
    'mn' => array(
    'Group' => 'Time',
    'Unit Name' => 'Minute',
    'AllowPrefix' => false 
    ),
    'sec' => array(
    'Group' => 'Time',
    'Unit Name' => 'Second',
    'AllowPrefix' => true 
    ),
    'Pa' => array(
    'Group' => 'Pressure',
    'Unit Name' => 'Pascal',
    'AllowPrefix' => true 
    ),
    'p' => array(
    'Group' => 'Pressure',
    'Unit Name' => 'Pascal',
    'AllowPrefix' => true 
    ),
    'atm' => array(
    'Group' => 'Pressure',
    'Unit Name' => 'Atmosphere',
    'AllowPrefix' => true 
    ),
    'at' => array(
    'Group' => 'Pressure',
    'Unit Name' => 'Atmosphere',
    'AllowPrefix' => true 
    ),
    'mmHg' => array(
    'Group' => 'Pressure',
    'Unit Name' => 'mm of Mercury',
    'AllowPrefix' => true 
    ),
    'N' => array(
    'Group' => 'Force',
    'Unit Name' => 'Newton',
    'AllowPrefix' => true 
    ),
    'dyn' => array(
    'Group' => 'Force',
    'Unit Name' => 'Dyne',
    'AllowPrefix' => true 
    ),
    'dy' => array(
    'Group' => 'Force',
    'Unit Name' => 'Dyne',
    'AllowPrefix' => true 
    ),
    'lbf' => array(
    'Group' => 'Force',
    'Unit Name' => 'Pound force',
    'AllowPrefix' => false 
    ),
    'J' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Joule',
    'AllowPrefix' => true 
    ),
    'e' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Erg',
    'AllowPrefix' => true 
    ),
    'c' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Thermodynamic calorie',
    'AllowPrefix' => true 
    ),
    'cal' => array(
    'Group' => 'Energy',
    'Unit Name' => 'IT calorie',
    'AllowPrefix' => true 
    ),
    'eV' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Electron volt',
    'AllowPrefix' => true 
    ),
    'ev' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Electron volt',
    'AllowPrefix' => true 
    ),
    'HPh' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Horsepower-hour',
    'AllowPrefix' => false 
    ),
    'hh' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Horsepower-hour',
    'AllowPrefix' => false 
    ),
    'Wh' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Watt-hour',
    'AllowPrefix' => true 
    ),
    'wh' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Watt-hour',
    'AllowPrefix' => true 
    ),
    'flb' => array(
    'Group' => 'Energy',
    'Unit Name' => 'Foot-pound',
    'AllowPrefix' => false 
    ),
    'BTU' => array(
    'Group' => 'Energy',
    'Unit Name' => 'BTU',
    'AllowPrefix' => false 
    ),
    'btu' => array(
    'Group' => 'Energy',
    'Unit Name' => 'BTU',
    'AllowPrefix' => false 
    ),
    'HP' => array(
    'Group' => 'Power',
    'Unit Name' => 'Horsepower',
    'AllowPrefix' => false 
    ),
    'h' => array(
    'Group' => 'Power',
    'Unit Name' => 'Horsepower',
    'AllowPrefix' => false 
    ),
    'W' => array(
    'Group' => 'Power',
    'Unit Name' => 'Watt',
    'AllowPrefix' => true 
    ),
    'w' => array(
    'Group' => 'Power',
    'Unit Name' => 'Watt',
    'AllowPrefix' => true 
    ),
    'T' => array(
    'Group' => 'Magnetism',
    'Unit Name' => 'Tesla',
    'AllowPrefix' => true 
    ),
    'ga' => array(
    'Group' => 'Magnetism',
    'Unit Name' => 'Gauss',
    'AllowPrefix' => true 
    ),
    'C' => array(
    'Group' => 'Temperature',
    'Unit Name' => 'Celsius',
    'AllowPrefix' => false 
    ),
    'cel' => array(
    'Group' => 'Temperature',
    'Unit Name' => 'Celsius',
    'AllowPrefix' => false 
    ),
    'F' => array(
    'Group' => 'Temperature',
    'Unit Name' => 'Fahrenheit',
    'AllowPrefix' => false 
    ),
    'fah' => array(
    'Group' => 'Temperature',
    'Unit Name' => 'Fahrenheit',
    'AllowPrefix' => false 
    ),
    'K' => array(
    'Group' => 'Temperature',
    'Unit Name' => 'Kelvin',
    'AllowPrefix' => false 
    ),
    'kel' => array(
    'Group' => 'Temperature',
    'Unit Name' => 'Kelvin',
    'AllowPrefix' => false 
    ),
    'tsp' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Teaspoon',
    'AllowPrefix' => false 
    ),
    'tbs' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Tablespoon',
    'AllowPrefix' => false 
    ),
    'oz' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Fluid Ounce',
    'AllowPrefix' => false 
    ),
    'cup' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Cup',
    'AllowPrefix' => false 
    ),
    'pt' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'U.S. Pint',
    'AllowPrefix' => false 
    ),
    'us_pt' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'U.S. Pint',
    'AllowPrefix' => false 
    ),
    'uk_pt' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'U.K. Pint',
    'AllowPrefix' => false 
    ),
    'qt' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Quart',
    'AllowPrefix' => false 
    ),
    'gal' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Gallon',
    'AllowPrefix' => false 
    ),
    'l' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Litre',
    'AllowPrefix' => true 
    ),
    'lt' => array(
    'Group' => 'Liquid',
    'Unit Name' => 'Litre',
    'AllowPrefix' => true 
    ) 
    );
    
    /**
     * Details of the Multiplier prefixes that can be used with Units of Measure in CONVERTUOM()
     *
     * @var mixed[]
     */
    private static $conversionMultipliers = array(
    'Y' => array(
    'multiplier' => 1E24,
    'name' => 'yotta' 
    ),
    'Z' => array(
    'multiplier' => 1E21,
    'name' => 'zetta' 
    ),
    'E' => array(
    'multiplier' => 1E18,
    'name' => 'exa' 
    ),
    'P' => array(
    'multiplier' => 1E15,
    'name' => 'peta' 
    ),
    'T' => array(
    'multiplier' => 1E12,
    'name' => 'tera' 
    ),
    'G' => array(
    'multiplier' => 1E9,
    'name' => 'giga' 
    ),
    'M' => array(
    'multiplier' => 1E6,
    'name' => 'mega' 
    ),
    'k' => array(
    'multiplier' => 1E3,
    'name' => 'kilo' 
    ),
    'h' => array(
    'multiplier' => 1E2,
    'name' => 'hecto' 
    ),
    'e' => array(
    'multiplier' => 1E1,
    'name' => 'deka' 
    ),
    'd' => array(
    'multiplier' => 1E-1,
    'name' => 'deci' 
    ),
    'c' => array(
    'multiplier' => 1E-2,
    'name' => 'centi' 
    ),
    'm' => array(
    'multiplier' => 1E-3,
    'name' => 'milli' 
    ),
    'u' => array(
    'multiplier' => 1E-6,
    'name' => 'micro' 
    ),
    'n' => array(
    'multiplier' => 1E-9,
    'name' => 'nano' 
    ),
    'p' => array(
    'multiplier' => 1E-12,
    'name' => 'pico' 
    ),
    'f' => array(
    'multiplier' => 1E-15,
    'name' => 'femto' 
    ),
    'a' => array(
    'multiplier' => 1E-18,
    'name' => 'atto' 
    ),
    'z' => array(
    'multiplier' => 1E-21,
    'name' => 'zepto' 
    ),
    'y' => array(
    'multiplier' => 1E-24,
    'name' => 'yocto' 
    ) 
    );
    
    /**
     * Details of the Units of measure conversion factors, organised by group
     *
     * @var mixed[]
     */
    private static $unitConversions = array(
    'Mass' => array(
    'g' => array(
    'g' => 1.0,
    'sg' => 6.85220500053478E-05,
    'lbm' => 2.20462291469134E-03,
    'u' => 6.02217000000000E+23,
    'ozm' => 3.52739718003627E-02 
    ),
    'sg' => array(
    'g' => 1.45938424189287E+04,
    'sg' => 1.0,
    'lbm' => 3.21739194101647E+01,
    'u' => 8.78866000000000E+27,
    'ozm' => 5.14782785944229E+02 
    ),
    'lbm' => array(
    'g' => 4.5359230974881148E+02,
    'sg' => 3.10810749306493E-02,
    'lbm' => 1.0,
    'u' => 2.73161000000000E+26,
    'ozm' => 1.60000023429410E+01 
    ),
    'u' => array(
    'g' => 1.66053100460465E-24,
    'sg' => 1.13782988532950E-28,
    'lbm' => 3.66084470330684E-27,
    'u' => 1.0,
    'ozm' => 5.85735238300524E-26 
    ),
    'ozm' => array(
    'g' => 2.83495152079732E+01,
    'sg' => 1.94256689870811E-03,
    'lbm' => 6.24999908478882E-02,
    'u' => 1.70725600000000E+25,
    'ozm' => 1.0 
    ) 
    ),
    'Distance' => array(
    'm' => array(
    'm' => 1.0,
    'mi' => 6.21371192237334E-04,
    'Nmi' => 5.39956803455724E-04,
    'in' => 3.93700787401575E+01,
    'ft' => 3.28083989501312E+00,
    'yd' => 1.09361329797891E+00,
    'ang' => 1.00000000000000E+10,
    'Pica' => 2.83464566929116E+03 
    ),
    'mi' => array(
    'm' => 1.60934400000000E+03,
    'mi' => 1.0,
    'Nmi' => 8.68976241900648E-01,
    'in' => 6.33600000000000E+04,
    'ft' => 5.28000000000000E+03,
    'yd' => 1.76000000000000E+03,
    'ang' => 1.60934400000000E+13,
    'Pica' => 4.56191999999971E+06 
    ),
    'Nmi' => array(
    'm' => 1.85200000000000E+03,
    'mi' => 1.15077944802354E+00,
    'Nmi' => 1.0,
    'in' => 7.29133858267717E+04,
    'ft' => 6.07611548556430E+03,
    'yd' => 2.02537182785694E+03,
    'ang' => 1.85200000000000E+13,
    'Pica' => 5.24976377952723E+06 
    ),
    'in' => array(
    'm' => 2.54000000000000E-02,
    'mi' => 1.57828282828283E-05,
    'Nmi' => 1.37149028077754E-05,
    'in' => 1.0,
    'ft' => 8.33333333333333E-02,
    'yd' => 2.77777777686643E-02,
    'ang' => 2.54000000000000E+08,
    'Pica' => 7.19999999999955E+01 
    ),
    'ft' => array(
    'm' => 3.04800000000000E-01,
    'mi' => 1.89393939393939E-04,
    'Nmi' => 1.64578833693305E-04,
    'in' => 1.20000000000000E+01,
    'ft' => 1.0,
    'yd' => 3.33333333223972E-01,
    'ang' => 3.04800000000000E+09,
    'Pica' => 8.63999999999946E+02 
    ),
    'yd' => array(
    'm' => 9.14400000300000E-01,
    'mi' => 5.68181818368230E-04,
    'Nmi' => 4.93736501241901E-04,
    'in' => 3.60000000118110E+01,
    'ft' => 3.00000000000000E+00,
    'yd' => 1.0,
    'ang' => 9.14400000300000E+09,
    'Pica' => 2.59200000085023E+03 
    ),
    'ang' => array(
    'm' => 1.00000000000000E-10,
    'mi' => 6.21371192237334E-14,
    'Nmi' => 5.39956803455724E-14,
    'in' => 3.93700787401575E-09,
    'ft' => 3.28083989501312E-10,
    'yd' => 1.09361329797891E-10,
    'ang' => 1.0,
    'Pica' => 2.83464566929116E-07 
    ),
    'Pica' => array(
    'm' => 3.52777777777800E-04,
    'mi' => 2.19205948372629E-07,
    'Nmi' => 1.90484761219114E-07,
    'in' => 1.38888888888898E-02,
    'ft' => 1.15740740740748E-03,
    'yd' => 3.85802469009251E-04,
    'ang' => 3.52777777777800E+06,
    'Pica' => 1.0 
    ) 
    ),
    'Time' => array(
    'yr' => array(
    'yr' => 1.0,
    'day' => 365.25,
    'hr' => 8766.0,
    'mn' => 525960.0,
    'sec' => 31557600.0 
    ),
    'day' => array(
    'yr' => 2.73785078713210E-03,
    'day' => 1.0,
    'hr' => 24.0,
    'mn' => 1440.0,
    'sec' => 86400.0 
    ),
    'hr' => array(
    'yr' => 1.14077116130504E-04,
    'day' => 4.16666666666667E-02,
    'hr' => 1.0,
    'mn' => 60.0,
    'sec' => 3600.0 
    ),
    'mn' => array(
    'yr' => 1.90128526884174E-06,
    'day' => 6.94444444444444E-04,
    'hr' => 1.66666666666667E-02,
    'mn' => 1.0,
    'sec' => 60.0 
    ),
    'sec' => array(
    'yr' => 3.16880878140289E-08,
    'day' => 1.15740740740741E-05,
    'hr' => 2.77777777777778E-04,
    'mn' => 1.66666666666667E-02,
    'sec' => 1.0 
    ) 
    ),
    'Pressure' => array(
    'Pa' => array(
    'Pa' => 1.0,
    'p' => 1.0,
    'atm' => 9.86923299998193E-06,
    'at' => 9.86923299998193E-06,
    'mmHg' => 7.50061707998627E-03 
    ),
    'p' => array(
    'Pa' => 1.0,
    'p' => 1.0,
    'atm' => 9.86923299998193E-06,
    'at' => 9.86923299998193E-06,
    'mmHg' => 7.50061707998627E-03 
    ),
    'atm' => array(
    'Pa' => 1.01324996583000E+05,
    'p' => 1.01324996583000E+05,
    'atm' => 1.0,
    'at' => 1.0,
    'mmHg' => 760.0 
    ),
    'at' => array(
    'Pa' => 1.01324996583000E+05,
    'p' => 1.01324996583000E+05,
    'atm' => 1.0,
    'at' => 1.0,
    'mmHg' => 760.0 
    ),
    'mmHg' => array(
    'Pa' => 1.33322363925000E+02,
    'p' => 1.33322363925000E+02,
    'atm' => 1.31578947368421E-03,
    'at' => 1.31578947368421E-03,
    'mmHg' => 1.0 
    ) 
    ),
    'Force' => array(
    'N' => array(
    'N' => 1.0,
    'dyn' => 1.0E+5,
    'dy' => 1.0E+5,
    'lbf' => 2.24808923655339E-01 
    ),
    'dyn' => array(
    'N' => 1.0E-5,
    'dyn' => 1.0,
    'dy' => 1.0,
    'lbf' => 2.24808923655339E-06 
    ),
    'dy' => array(
    'N' => 1.0E-5,
    'dyn' => 1.0,
    'dy' => 1.0,
    'lbf' => 2.24808923655339E-06 
    ),
    'lbf' => array(
    'N' => 4.448222,
    'dyn' => 4.448222E+5,
    'dy' => 4.448222E+5,
    'lbf' => 1.0 
    ) 
    ),
    'Energy' => array(
    'J' => array(
    'J' => 1.0,
    'e' => 9.99999519343231E+06,
    'c' => 2.39006249473467E-01,
    'cal' => 2.38846190642017E-01,
    'eV' => 6.24145700000000E+18,
    'ev' => 6.24145700000000E+18,
    'HPh' => 3.72506430801000E-07,
    'hh' => 3.72506430801000E-07,
    'Wh' => 2.77777916238711E-04,
    'wh' => 2.77777916238711E-04,
    'flb' => 2.37304222192651E+01,
    'BTU' => 9.47815067349015E-04,
    'btu' => 9.47815067349015E-04 
    ),
    'e' => array(
    'J' => 1.00000048065700E-07,
    'e' => 1.0,
    'c' => 2.39006364353494E-08,
    'cal' => 2.38846305445111E-08,
    'eV' => 6.24146000000000E+11,
    'ev' => 6.24146000000000E+11,
    'HPh' => 3.72506609848824E-14,
    'hh' => 3.72506609848824E-14,
    'Wh' => 2.77778049754611E-11,
    'wh' => 2.77778049754611E-11,
    'flb' => 2.37304336254586E-06,
    'BTU' => 9.47815522922962E-11,
    'btu' => 9.47815522922962E-11 
    ),
    'c' => array(
    'J' => 4.18399101363672E+00,
    'e' => 4.18398900257312E+07,
    'c' => 1.0,
    'cal' => 9.99330315287563E-01,
    'eV' => 2.61142000000000E+19,
    'ev' => 2.61142000000000E+19,
    'HPh' => 1.55856355899327E-06,
    'hh' => 1.55856355899327E-06,
    'Wh' => 1.16222030532950E-03,
    'wh' => 1.16222030532950E-03,
    'flb' => 9.92878733152102E+01,
    'BTU' => 3.96564972437776E-03,
    'btu' => 3.96564972437776E-03 
    ),
    'cal' => array(
    'J' => 4.18679484613929E+00,
    'e' => 4.18679283372801E+07,
    'c' => 1.00067013349059E+00,
    'cal' => 1.0,
    'eV' => 2.61317000000000E+19,
    'ev' => 2.61317000000000E+19,
    'HPh' => 1.55960800463137E-06,
    'hh' => 1.55960800463137E-06,
    'Wh' => 1.16299914807955E-03,
    'wh' => 1.16299914807955E-03,
    'flb' => 9.93544094443283E+01,
    'BTU' => 3.96830723907002E-03,
    'btu' => 3.96830723907002E-03 
    ),
    'eV' => array(
    'J' => 1.60219000146921E-19,
    'e' => 1.60218923136574E-12,
    'c' => 3.82933423195043E-20,
    'cal' => 3.82676978535648E-20,
    'eV' => 1.0,
    'ev' => 1.0,
    'HPh' => 5.96826078912344E-26,
    'hh' => 5.96826078912344E-26,
    'Wh' => 4.45053000026614E-23,
    'wh' => 4.45053000026614E-23,
    'flb' => 3.80206452103492E-18,
    'BTU' => 1.51857982414846E-22,
    'btu' => 1.51857982414846E-22 
    ),
    'ev' => array(
    'J' => 1.60219000146921E-19,
    'e' => 1.60218923136574E-12,
    'c' => 3.82933423195043E-20,
    'cal' => 3.82676978535648E-20,
    'eV' => 1.0,
    'ev' => 1.0,
    'HPh' => 5.96826078912344E-26,
    'hh' => 5.96826078912344E-26,
    'Wh' => 4.45053000026614E-23,
    'wh' => 4.45053000026614E-23,
    'flb' => 3.80206452103492E-18,
    'BTU' => 1.51857982414846E-22,
    'btu' => 1.51857982414846E-22 
    ),
    'HPh' => array(
    'J' => 2.68451741316170E+06,
    'e' => 2.68451612283024E+13,
    'c' => 6.41616438565991E+05,
    'cal' => 6.41186757845835E+05,
    'eV' => 1.67553000000000E+25,
    'ev' => 1.67553000000000E+25,
    'HPh' => 1.0,
    'hh' => 1.0,
    'Wh' => 7.45699653134593E+02,
    'wh' => 7.45699653134593E+02,
    'flb' => 6.37047316692964E+07,
    'BTU' => 2.54442605275546E+03,
    'btu' => 2.54442605275546E+03 
    ),
    'hh' => array(
    'J' => 2.68451741316170E+06,
    'e' => 2.68451612283024E+13,
    'c' => 6.41616438565991E+05,
    'cal' => 6.41186757845835E+05,
    'eV' => 1.67553000000000E+25,
    'ev' => 1.67553000000000E+25,
    'HPh' => 1.0,
    'hh' => 1.0,
    'Wh' => 7.45699653134593E+02,
    'wh' => 7.45699653134593E+02,
    'flb' => 6.37047316692964E+07,
    'BTU' => 2.54442605275546E+03,
    'btu' => 2.54442605275546E+03 
    ),
    'Wh' => array(
    'J' => 3.59999820554720E+03,
    'e' => 3.59999647518369E+10,
    'c' => 8.60422069219046E+02,
    'cal' => 8.59845857713046E+02,
    'eV' => 2.24692340000000E+22,
    'ev' => 2.24692340000000E+22,
    'HPh' => 1.34102248243839E-03,
    'hh' => 1.34102248243839E-03,
    'Wh' => 1.0,
    'wh' => 1.0,
    'flb' => 8.54294774062316E+04,
    'BTU' => 3.41213254164705E+00,
    'btu' => 3.41213254164705E+00 
    ),
    'wh' => array(
    'J' => 3.59999820554720E+03,
    'e' => 3.59999647518369E+10,
    'c' => 8.60422069219046E+02,
    'cal' => 8.59845857713046E+02,
    'eV' => 2.24692340000000E+22,
    'ev' => 2.24692340000000E+22,
    'HPh' => 1.34102248243839E-03,
    'hh' => 1.34102248243839E-03,
    'Wh' => 1.0,
    'wh' => 1.0,
    'flb' => 8.54294774062316E+04,
    'BTU' => 3.41213254164705E+00,
    'btu' => 3.41213254164705E+00 
    ),
    'flb' => array(
    'J' => 4.21400003236424E-02,
    'e' => 4.21399800687660E+05,
    'c' => 1.00717234301644E-02,
    'cal' => 1.00649785509554E-02,
    'eV' => 2.63015000000000E+17,
    'ev' => 2.63015000000000E+17,
    'HPh' => 1.56974211145130E-08,
    'hh' => 1.56974211145130E-08,
    'Wh' => 1.17055614802000E-05,
    'wh' => 1.17055614802000E-05,
    'flb' => 1.0,
    'BTU' => 3.99409272448406E-05,
    'btu' => 3.99409272448406E-05 
    ),
    'BTU' => array(
    'J' => 1.05505813786749E+03,
    'e' => 1.05505763074665E+10,
    'c' => 2.52165488508168E+02,
    'cal' => 2.51996617135510E+02,
    'eV' => 6.58510000000000E+21,
    'ev' => 6.58510000000000E+21,
    'HPh' => 3.93015941224568E-04,
    'hh' => 3.93015941224568E-04,
    'Wh' => 2.93071851047526E-01,
    'wh' => 2.93071851047526E-01,
    'flb' => 2.50369750774671E+04,
    'BTU' => 1.0,
    'btu' => 1.0 
    ),
    'btu' => array(
    'J' => 1.05505813786749E+03,
    'e' => 1.05505763074665E+10,
    'c' => 2.52165488508168E+02,
    'cal' => 2.51996617135510E+02,
    'eV' => 6.58510000000000E+21,
    'ev' => 6.58510000000000E+21,
    'HPh' => 3.93015941224568E-04,
    'hh' => 3.93015941224568E-04,
    'Wh' => 2.93071851047526E-01,
    'wh' => 2.93071851047526E-01,
    'flb' => 2.50369750774671E+04,
    'BTU' => 1.0,
    'btu' => 1.0 
    ) 
    ),
    'Power' => array(
    'HP' => array(
    'HP' => 1.0,
    'h' => 1.0,
    'W' => 7.45701000000000E+02,
    'w' => 7.45701000000000E+02 
    ),
    'h' => array(
    'HP' => 1.0,
    'h' => 1.0,
    'W' => 7.45701000000000E+02,
    'w' => 7.45701000000000E+02 
    ),
    'W' => array(
    'HP' => 1.34102006031908E-03,
    'h' => 1.34102006031908E-03,
    'W' => 1.0,
    'w' => 1.0 
    ),
    'w' => array(
    'HP' => 1.34102006031908E-03,
    'h' => 1.34102006031908E-03,
    'W' => 1.0,
    'w' => 1.0 
    ) 
    ),
    'Magnetism' => array(
    'T' => array(
    'T' => 1.0,
    'ga' => 10000.0 
    ),
    'ga' => array(
    'T' => 0.0001,
    'ga' => 1.0 
    ) 
    ),
    'Liquid' => array(
    'tsp' => array(
    'tsp' => 1.0,
    'tbs' => 3.33333333333333E-01,
    'oz' => 1.66666666666667E-01,
    'cup' => 2.08333333333333E-02,
    'pt' => 1.04166666666667E-02,
    'us_pt' => 1.04166666666667E-02,
    'uk_pt' => 8.67558516821960E-03,
    'qt' => 5.20833333333333E-03,
    'gal' => 1.30208333333333E-03,
    'l' => 4.92999408400710E-03,
    'lt' => 4.92999408400710E-03 
    ),
    'tbs' => array(
    'tsp' => 3.00000000000000E+00,
    'tbs' => 1.0,
    'oz' => 5.00000000000000E-01,
    'cup' => 6.25000000000000E-02,
    'pt' => 3.12500000000000E-02,
    'us_pt' => 3.12500000000000E-02,
    'uk_pt' => 2.60267555046588E-02,
    'qt' => 1.56250000000000E-02,
    'gal' => 3.90625000000000E-03,
    'l' => 1.47899822520213E-02,
    'lt' => 1.47899822520213E-02 
    ),
    'oz' => array(
    'tsp' => 6.00000000000000E+00,
    'tbs' => 2.00000000000000E+00,
    'oz' => 1.0,
    'cup' => 1.25000000000000E-01,
    'pt' => 6.25000000000000E-02,
    'us_pt' => 6.25000000000000E-02,
    'uk_pt' => 5.20535110093176E-02,
    'qt' => 3.12500000000000E-02,
    'gal' => 7.81250000000000E-03,
    'l' => 2.95799645040426E-02,
    'lt' => 2.95799645040426E-02 
    ),
    'cup' => array(
    'tsp' => 4.80000000000000E+01,
    'tbs' => 1.60000000000000E+01,
    'oz' => 8.00000000000000E+00,
    'cup' => 1.0,
    'pt' => 5.00000000000000E-01,
    'us_pt' => 5.00000000000000E-01,
    'uk_pt' => 4.16428088074541E-01,
    'qt' => 2.50000000000000E-01,
    'gal' => 6.25000000000000E-02,
    'l' => 2.36639716032341E-01,
    'lt' => 2.36639716032341E-01 
    ),
    'pt' => array(
    'tsp' => 9.60000000000000E+01,
    'tbs' => 3.20000000000000E+01,
    'oz' => 1.60000000000000E+01,
    'cup' => 2.00000000000000E+00,
    'pt' => 1.0,
    'us_pt' => 1.0,
    'uk_pt' => 8.32856176149081E-01,
    'qt' => 5.00000000000000E-01,
    'gal' => 1.25000000000000E-01,
    'l' => 4.73279432064682E-01,
    'lt' => 4.73279432064682E-01 
    ),
    'us_pt' => array(
    'tsp' => 9.60000000000000E+01,
    'tbs' => 3.20000000000000E+01,
    'oz' => 1.60000000000000E+01,
    'cup' => 2.00000000000000E+00,
    'pt' => 1.0,
    'us_pt' => 1.0,
    'uk_pt' => 8.32856176149081E-01,
    'qt' => 5.00000000000000E-01,
    'gal' => 1.25000000000000E-01,
    'l' => 4.73279432064682E-01,
    'lt' => 4.73279432064682E-01 
    ),
    'uk_pt' => array(
    'tsp' => 1.15266000000000E+02,
    'tbs' => 3.84220000000000E+01,
    'oz' => 1.92110000000000E+01,
    'cup' => 2.40137500000000E+00,
    'pt' => 1.20068750000000E+00,
    'us_pt' => 1.20068750000000E+00,
    'uk_pt' => 1.0,
    'qt' => 6.00343750000000E-01,
    'gal' => 1.50085937500000E-01,
    'l' => 5.68260698087162E-01,
    'lt' => 5.68260698087162E-01 
    ),
    'qt' => array(
    'tsp' => 1.92000000000000E+02,
    'tbs' => 6.40000000000000E+01,
    'oz' => 3.20000000000000E+01,
    'cup' => 4.00000000000000E+00,
    'pt' => 2.00000000000000E+00,
    'us_pt' => 2.00000000000000E+00,
    'uk_pt' => 1.66571235229816E+00,
    'qt' => 1.0,
    'gal' => 2.50000000000000E-01,
    'l' => 9.46558864129363E-01,
    'lt' => 9.46558864129363E-01 
    ),
    'gal' => array(
    'tsp' => 7.68000000000000E+02,
    'tbs' => 2.56000000000000E+02,
    'oz' => 1.28000000000000E+02,
    'cup' => 1.60000000000000E+01,
    'pt' => 8.00000000000000E+00,
    'us_pt' => 8.00000000000000E+00,
    'uk_pt' => 6.66284940919265E+00,
    'qt' => 4.00000000000000E+00,
    'gal' => 1.0,
    'l' => 3.78623545651745E+00,
    'lt' => 3.78623545651745E+00 
    ),
    'l' => array(
    'tsp' => 2.02840000000000E+02,
    'tbs' => 6.76133333333333E+01,
    'oz' => 3.38066666666667E+01,
    'cup' => 4.22583333333333E+00,
    'pt' => 2.11291666666667E+00,
    'us_pt' => 2.11291666666667E+00,
    'uk_pt' => 1.75975569552166E+00,
    'qt' => 1.05645833333333E+00,
    'gal' => 2.64114583333333E-01,
    'l' => 1.0,
    'lt' => 1.0 
    ),
    'lt' => array(
    'tsp' => 2.02840000000000E+02,
    'tbs' => 6.76133333333333E+01,
    'oz' => 3.38066666666667E+01,
    'cup' => 4.22583333333333E+00,
    'pt' => 2.11291666666667E+00,
    'us_pt' => 2.11291666666667E+00,
    'uk_pt' => 1.75975569552166E+00,
    'qt' => 1.05645833333333E+00,
    'gal' => 2.64114583333333E-01,
    'l' => 1.0,
    'lt' => 1.0 
    ) 
    ) 
    );
    
    /**
     * parseComplex
     *
     * Parses a complex number into its real and imaginary parts, and an I or J suffix
     *
     * @param string $complexNumber
     *            The complex number
     * @return string[] Indexed on "real", "imaginary" and "suffix"
     */
    public static function parseComplex($complexNumber) {
        $workString = (string) $complexNumber;
        
        $realNumber = $imaginary = 0;
        // Extract the suffix, if there is one
        $suffix = substr($workString, -1);
        if (!is_numeric($suffix)) {
            $workString = substr($workString, 0, -1);
        } else {
            $suffix = '';
        }
        
        // Split the input into its Real and Imaginary components
        $leadingSign = 0;
        if (strlen($workString) > 0) {
            $leadingSign = (($workString{0} == '+') || ($workString{0} == '-')) ? 1 : 0;
        }
        $power = '';
        $realNumber = strtok($workString, '+-');
        if (strtoupper(substr($realNumber, -1)) == 'E') {
            $power = strtok('+-');
            ++$leadingSign;
        }
        
        $realNumber = substr($workString, 0, strlen($realNumber) + strlen($power) + $leadingSign);
        
        if ($suffix != '') {
            $imaginary = substr($workString, strlen($realNumber));
            
            if (($imaginary == '') && (($realNumber == '') || ($realNumber == '+') || ($realNumber == '-'))) {
                $imaginary = $realNumber . '1';
                $realNumber = '0';
            } elseif ($imaginary == '') {
                $imaginary = $realNumber;
                $realNumber = '0';
            } elseif (($imaginary == '+') || ($imaginary == '-')) {
                $imaginary .= '1';
            }
        }
        
        return array(
        'real' => $realNumber,
        'imaginary' => $imaginary,
        'suffix' => $suffix 
        );
    }
    
    /**
     * Cleans the leading characters in a complex number string
     *
     * @param string $complexNumber
     *            The complex number to clean
     * @return string The "cleaned" complex number
     */
    private static function cleanComplex($complexNumber) {
        if ($complexNumber{0} == '+') {
            $complexNumber = substr($complexNumber, 1);
        }
        if ($complexNumber{0} == '0') {
            $complexNumber = substr($complexNumber, 1);
        }
        if ($complexNumber{0} == '.') {
            $complexNumber = '0' . $complexNumber;
        }
        if ($complexNumber{0} == '+') {
            $complexNumber = substr($complexNumber, 1);
        }
        return $complexNumber;
    }
    
    /**
     * Formats a number base string value with leading zeroes
     *
     * @param string $xVal
     *            The "number" to pad
     * @param integer $places
     *            The length that we want to pad this value
     * @return string The padded "number"
     */
    private static function nbrConversionFormat($xVal, $places) {
        if (!is_null($places)) {
            if (is_numeric($places)) {
                $places = (int) $places;
            } else {
                return Functions::VALUE();
            }
            if ($places < 0) {
                return Functions::NAN();
            }
            if (strlen($xVal) <= $places) {
                return substr(str_pad($xVal, $places, '0', STR_PAD_LEFT), -10);
            } else {
                return Functions::NAN();
            }
        }
        
        return substr($xVal, -10);
    }
    
    /**
     * BESSELI
     *
     * Returns the modified Bessel function In(x), which is equivalent to the Bessel function evaluated
     * for purely imaginary arguments
     *
     * Excel Function:
     * BESSELI(x,ord)
     *
     * @access public
     * @category Engineering Functions
     * @param float $x
     *            The value at which to evaluate the function.
     *            If x is nonnumeric, BESSELI returns the #VALUE! error value.
     * @param integer $ord
     *            The order of the Bessel function.
     *            If ord is not an integer, it is truncated.
     *            If $ord is nonnumeric, BESSELI returns the #VALUE! error value.
     *            If $ord < 0, BESSELI returns the #NUM! error value.
     * @return float
     *
     */
    public static function BESSELI($x, $ord) {
        $x = (is_null($x)) ? 0.0 : Functions::flattenSingleValue($x);
        $ord = (is_null($ord)) ? 0.0 : Functions::flattenSingleValue($ord);
        
        if ((is_numeric($x)) && (is_numeric($ord))) {
            $ord = floor($ord);
            if ($ord < 0) {
                return Functions::NAN();
            }
            
            if (abs($x) <= 30) {
                $fResult = $fTerm = pow($x / 2, $ord) / MathTrig::FACT($ord);
                $ordK = 1;
                $fSqrX = ($x * $x) / 4;
                do {
                    $fTerm *= $fSqrX;
                    $fTerm /= ($ordK * ($ordK + $ord));
                    $fResult += $fTerm;
                } while ( (abs($fTerm) > 1e-12) && (++$ordK < 100) );
            } else {
                $f_2_PI = 2 * M_PI;
                
                $fXAbs = abs($x);
                $fResult = exp($fXAbs) / sqrt($f_2_PI * $fXAbs);
                if (($ord & 1) && ($x < 0)) {
                    $fResult = -$fResult;
                }
            }
            return (is_nan($fResult)) ? Functions::NAN() : $fResult;
        }
        return Functions::VALUE();
    }
    
    /**
     * BESSELJ
     *
     * Returns the Bessel function
     *
     * Excel Function:
     * BESSELJ(x,ord)
     *
     * @access public
     * @category Engineering Functions
     * @param float $x
     *            The value at which to evaluate the function.
     *            If x is nonnumeric, BESSELJ returns the #VALUE! error value.
     * @param integer $ord
     *            The order of the Bessel function. If n is not an integer, it is truncated.
     *            If $ord is nonnumeric, BESSELJ returns the #VALUE! error value.
     *            If $ord < 0, BESSELJ returns the #NUM! error value.
     * @return float
     *
     */
    public static function BESSELJ($x, $ord) {
        $x = (is_null($x)) ? 0.0 : Functions::flattenSingleValue($x);
        $ord = (is_null($ord)) ? 0.0 : Functions::flattenSingleValue($ord);
        
        if ((is_numeric($x)) && (is_numeric($ord))) {
            $ord = floor($ord);
            if ($ord < 0) {
                return Functions::NAN();
            }
            
            $fResult = 0;
            if (abs($x) <= 30) {
                $fResult = $fTerm = pow($x / 2, $ord) / MathTrig::FACT($ord);
                $ordK = 1;
                $fSqrX = ($x * $x) / -4;
                do {
                    $fTerm *= $fSqrX;
                    $fTerm /= ($ordK * ($ordK + $ord));
                    $fResult += $fTerm;
                } while ( (abs($fTerm) > 1e-12) && (++$ordK < 100) );
            } else {
                $f_PI_DIV_2 = M_PI / 2;
                $f_PI_DIV_4 = M_PI / 4;
                
                $fXAbs = abs($x);
                $fResult = sqrt(M_2DIVPI / $fXAbs) * cos($fXAbs - $ord * $f_PI_DIV_2 - $f_PI_DIV_4);
                if (($ord & 1) && ($x < 0)) {
                    $fResult = -$fResult;
                }
            }
            return (is_nan($fResult)) ? Functions::NAN() : $fResult;
        }
        return Functions::VALUE();
    }
    private static function besselK0($fNum) {
        if ($fNum <= 2) {
            $fNum2 = $fNum * 0.5;
            $y = ($fNum2 * $fNum2);
            $fRet = -log($fNum2) * self::BESSELI($fNum, 0) + (-0.57721566 + $y * (0.42278420 + $y * (0.23069756 + $y * (0.3488590e-1 + $y * (0.262698e-2 + $y * (0.10750e-3 + $y * 0.74e-5))))));
        } else {
            $y = 2 / $fNum;
            $fRet = exp(-$fNum) / sqrt($fNum) * (1.25331414 + $y * (-0.7832358e-1 + $y * (0.2189568e-1 + $y * (-0.1062446e-1 + $y * (0.587872e-2 + $y * (-0.251540e-2 + $y * 0.53208e-3))))));
        }
        return $fRet;
    }
    private static function besselK1($fNum) {
        if ($fNum <= 2) {
            $fNum2 = $fNum * 0.5;
            $y = ($fNum2 * $fNum2);
            $fRet = log($fNum2) * self::BESSELI($fNum, 1) + (1 + $y * (0.15443144 + $y * (-0.67278579 + $y * (-0.18156897 + $y * (-0.1919402e-1 + $y * (-0.110404e-2 + $y * (-0.4686e-4))))))) / $fNum;
        } else {
            $y = 2 / $fNum;
            $fRet = exp(-$fNum) / sqrt($fNum) * (1.25331414 + $y * (0.23498619 + $y * (-0.3655620e-1 + $y * (0.1504268e-1 + $y * (-0.780353e-2 + $y * (0.325614e-2 + $y * (-0.68245e-3)))))));
        }
        return $fRet;
    }
    
    /**
     * BESSELK
     *
     * Returns the modified Bessel function Kn(x), which is equivalent to the Bessel functions evaluated
     * for purely imaginary arguments.
     *
     * Excel Function:
     * BESSELK(x,ord)
     *
     * @access public
     * @category Engineering Functions
     * @param float $x
     *            The value at which to evaluate the function.
     *            If x is nonnumeric, BESSELK returns the #VALUE! error value.
     * @param integer $ord
     *            The order of the Bessel function. If n is not an integer, it is truncated.
     *            If $ord is nonnumeric, BESSELK returns the #VALUE! error value.
     *            If $ord < 0, BESSELK returns the #NUM! error value.
     * @return float
     *
     */
    public static function BESSELK($x, $ord) {
        $x = (is_null($x)) ? 0.0 : Functions::flattenSingleValue($x);
        $ord = (is_null($ord)) ? 0.0 : Functions::flattenSingleValue($ord);
        
        if ((is_numeric($x)) && (is_numeric($ord))) {
            if (($ord < 0) || ($x == 0.0)) {
                return Functions::NAN();
            }
            
            switch (floor($ord)) {
                case 0 :
                    return self::besselK0($x);
                case 1 :
                    return self::besselK1($x);
                default :
                    $fTox = 2 / $x;
                    $fBkm = self::besselK0($x);
                    $fBk = self::besselK1($x);
                    for($n = 1; $n < $ord; ++$n) {
                        $fBkp = $fBkm + $n * $fTox * $fBk;
                        $fBkm = $fBk;
                        $fBk = $fBkp;
                    }
            }
            return (is_nan($fBk)) ? Functions::NAN() : $fBk;
        }
        return Functions::VALUE();
    }
    private static function besselY0($fNum) {
        if ($fNum < 8.0) {
            $y = ($fNum * $fNum);
            $f1 = -2957821389.0 + $y * (7062834065.0 + $y * (-512359803.6 + $y * (10879881.29 + $y * (-86327.92757 + $y * 228.4622733))));
            $f2 = 40076544269.0 + $y * (745249964.8 + $y * (7189466.438 + $y * (47447.26470 + $y * (226.1030244 + $y))));
            $fRet = $f1 / $f2 + 0.636619772 * self::BESSELJ($fNum, 0) * log($fNum);
        } else {
            $z = 8.0 / $fNum;
            $y = ($z * $z);
            $xx = $fNum - 0.785398164;
            $f1 = 1 + $y * (-0.1098628627e-2 + $y * (0.2734510407e-4 + $y * (-0.2073370639e-5 + $y * 0.2093887211e-6)));
            $f2 = -0.1562499995e-1 + $y * (0.1430488765e-3 + $y * (-0.6911147651e-5 + $y * (0.7621095161e-6 + $y * (-0.934945152e-7))));
            $fRet = sqrt(0.636619772 / $fNum) * (sin($xx) * $f1 + $z * cos($xx) * $f2);
        }
        return $fRet;
    }
    private static function besselY1($fNum) {
        if ($fNum < 8.0) {
            $y = ($fNum * $fNum);
            $f1 = $fNum * (-0.4900604943e13 + $y * (0.1275274390e13 + $y * (-0.5153438139e11 + $y * (0.7349264551e9 + $y * (-0.4237922726e7 + $y * 0.8511937935e4)))));
            $f2 = 0.2499580570e14 + $y * (0.4244419664e12 + $y * (0.3733650367e10 + $y * (0.2245904002e8 + $y * (0.1020426050e6 + $y * (0.3549632885e3 + $y)))));
            $fRet = $f1 / $f2 + 0.636619772 * (self::BESSELJ($fNum, 1) * log($fNum) - 1 / $fNum);
        } else {
            $fRet = sqrt(0.636619772 / $fNum) * sin($fNum - 2.356194491);
        }
        return $fRet;
    }
    
    /**
     * BESSELY
     *
     * Returns the Bessel function, which is also called the Weber function or the Neumann function.
     *
     * Excel Function:
     * BESSELY(x,ord)
     *
     * @access public
     * @category Engineering Functions
     * @param float $x
     *            The value at which to evaluate the function.
     *            If x is nonnumeric, BESSELK returns the #VALUE! error value.
     * @param integer $ord
     *            The order of the Bessel function. If n is not an integer, it is truncated.
     *            If $ord is nonnumeric, BESSELK returns the #VALUE! error value.
     *            If $ord < 0, BESSELK returns the #NUM! error value.
     *            
     * @return float
     */
    public static function BESSELY($x, $ord) {
        $x = (is_null($x)) ? 0.0 : Functions::flattenSingleValue($x);
        $ord = (is_null($ord)) ? 0.0 : Functions::flattenSingleValue($ord);
        
        if ((is_numeric($x)) && (is_numeric($ord))) {
            if (($ord < 0) || ($x == 0.0)) {
                return Functions::NAN();
            }
            
            switch (floor($ord)) {
                case 0 :
                    return self::besselY0($x);
                case 1 :
                    return self::besselY1($x);
                default :
                    $fTox = 2 / $x;
                    $fBym = self::besselY0($x);
                    $fBy = self::besselY1($x);
                    for($n = 1; $n < $ord; ++$n) {
                        $fByp = $n * $fTox * $fBy - $fBym;
                        $fBym = $fBy;
                        $fBy = $fByp;
                    }
            }
            return (is_nan($fBy)) ? Functions::NAN() : $fBy;
        }
        return Functions::VALUE();
    }
    
    /**
     * BINTODEC
     *
     * Return a binary value as decimal.
     *
     * Excel Function:
     * BIN2DEC(x)
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The binary number (as a string) that you want to convert. The number
     *            cannot contain more than 10 characters (10 bits). The most significant
     *            bit of number is the sign bit. The remaining 9 bits are magnitude bits.
     *            Negative numbers are represented using two's-complement notation.
     *            If number is not a valid binary number, or if number contains more than
     *            10 characters (10 bits), BIN2DEC returns the #NUM! error value.
     * @return string
     */
    public static function BINTODEC($x) {
        $x = Functions::flattenSingleValue($x);
        
        if (is_bool($x)) {
            if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
                $x = (int) $x;
            } else {
                return Functions::VALUE();
            }
        }
        if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_GNUMERIC) {
            $x = floor($x);
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[01]/', $x, $out)) {
            return Functions::NAN();
        }
        if (strlen($x) > 10) {
            return Functions::NAN();
        } elseif (strlen($x) == 10) {
            // Two's Complement
            $x = substr($x, -9);
            return '-' . (512 - bindec($x));
        }
        return bindec($x);
    }
    
    /**
     * BINTOHEX
     *
     * Return a binary value as hex.
     *
     * Excel Function:
     * BIN2HEX(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The binary number (as a string) that you want to convert. The number
     *            cannot contain more than 10 characters (10 bits). The most significant
     *            bit of number is the sign bit. The remaining 9 bits are magnitude bits.
     *            Negative numbers are represented using two's-complement notation.
     *            If number is not a valid binary number, or if number contains more than
     *            10 characters (10 bits), BIN2HEX returns the #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, BIN2HEX uses the
     *            minimum number of characters necessary. Places is useful for padding the
     *            return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, BIN2HEX returns the #VALUE! error value.
     *            If places is negative, BIN2HEX returns the #NUM! error value.
     * @return string
     */
    public static function BINTOHEX($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        // Argument X
        if (is_bool($x)) {
            if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
                $x = (int) $x;
            } else {
                return Functions::VALUE();
            }
        }
        if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_GNUMERIC) {
            $x = floor($x);
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[01]/', $x, $out)) {
            return Functions::NAN();
        }
        if (strlen($x) > 10) {
            return Functions::NAN();
        } elseif (strlen($x) == 10) {
            // Two's Complement
            return str_repeat('F', 8) . substr(strtoupper(dechex(bindec(substr($x, -9)))), -2);
        }
        $hexVal = (string) strtoupper(dechex(bindec($x)));
        
        return self::nbrConversionFormat($hexVal, $places);
    }
    
    /**
     * BINTOOCT
     *
     * Return a binary value as octal.
     *
     * Excel Function:
     * BIN2OCT(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The binary number (as a string) that you want to convert. The number
     *            cannot contain more than 10 characters (10 bits). The most significant
     *            bit of number is the sign bit. The remaining 9 bits are magnitude bits.
     *            Negative numbers are represented using two's-complement notation.
     *            If number is not a valid binary number, or if number contains more than
     *            10 characters (10 bits), BIN2OCT returns the #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, BIN2OCT uses the
     *            minimum number of characters necessary. Places is useful for padding the
     *            return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, BIN2OCT returns the #VALUE! error value.
     *            If places is negative, BIN2OCT returns the #NUM! error value.
     * @return string
     */
    public static function BINTOOCT($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
                $x = (int) $x;
            } else {
                return Functions::VALUE();
            }
        }
        if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_GNUMERIC) {
            $x = floor($x);
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[01]/', $x, $out)) {
            return Functions::NAN();
        }
        if (strlen($x) > 10) {
            return Functions::NAN();
        } elseif (strlen($x) == 10) {
            // Two's Complement
            return str_repeat('7', 7) . substr(strtoupper(decoct(bindec(substr($x, -9)))), -3);
        }
        $octVal = (string) decoct(bindec($x));
        
        return self::nbrConversionFormat($octVal, $places);
    }
    
    /**
     * DECTOBIN
     *
     * Return a decimal value as binary.
     *
     * Excel Function:
     * DEC2BIN(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The decimal integer you want to convert. If number is negative,
     *            valid place values are ignored and DEC2BIN returns a 10-character
     *            (10-bit) binary number in which the most significant bit is the sign
     *            bit. The remaining 9 bits are magnitude bits. Negative numbers are
     *            represented using two's-complement notation.
     *            If number < -512 or if number > 511, DEC2BIN returns the #NUM! error
     *            value.
     *            If number is nonnumeric, DEC2BIN returns the #VALUE! error value.
     *            If DEC2BIN requires more than places characters, it returns the #NUM!
     *            error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, DEC2BIN uses
     *            the minimum number of characters necessary. Places is useful for
     *            padding the return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, DEC2BIN returns the #VALUE! error value.
     *            If places is zero or negative, DEC2BIN returns the #NUM! error value.
     * @return string
     */
    public static function DECTOBIN($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
                $x = (int) $x;
            } else {
                return Functions::VALUE();
            }
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[-0123456789.]/', $x, $out)) {
            return Functions::VALUE();
        }
        $x = (string) floor($x);
        $r = decbin($x);
        if (strlen($r) == 32) {
            // Two's Complement
            $r = substr($r, -10);
        } elseif (strlen($r) >= 11) {
            return Functions::NAN();
        }
        
        return self::nbrConversionFormat($r, $places);
    }
    
    /**
     * DECTOHEX
     *
     * Return a decimal value as hex.
     *
     * Excel Function:
     * DEC2HEX(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The decimal integer you want to convert. If number is negative,
     *            places is ignored and DEC2HEX returns a 10-character (40-bit)
     *            hexadecimal number in which the most significant bit is the sign
     *            bit. The remaining 39 bits are magnitude bits. Negative numbers
     *            are represented using two's-complement notation.
     *            If number < -549,755,813,888 or if number > 549,755,813,887,
     *            DEC2HEX returns the #NUM! error value.
     *            If number is nonnumeric, DEC2HEX returns the #VALUE! error value.
     *            If DEC2HEX requires more than places characters, it returns the
     *            #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, DEC2HEX uses
     *            the minimum number of characters necessary. Places is useful for
     *            padding the return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, DEC2HEX returns the #VALUE! error value.
     *            If places is zero or negative, DEC2HEX returns the #NUM! error value.
     * @return string
     */
    public static function DECTOHEX($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
                $x = (int) $x;
            } else {
                return Functions::VALUE();
            }
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[-0123456789.]/', $x, $out)) {
            return Functions::VALUE();
        }
        $x = (string) floor($x);
        $r = strtoupper(dechex($x));
        if (strlen($r) == 8) {
            // Two's Complement
            $r = 'FF' . $r;
        }
        
        return self::nbrConversionFormat($r, $places);
    }
    
    /**
     * DECTOOCT
     *
     * Return an decimal value as octal.
     *
     * Excel Function:
     * DEC2OCT(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The decimal integer you want to convert. If number is negative,
     *            places is ignored and DEC2OCT returns a 10-character (30-bit)
     *            octal number in which the most significant bit is the sign bit.
     *            The remaining 29 bits are magnitude bits. Negative numbers are
     *            represented using two's-complement notation.
     *            If number < -536,870,912 or if number > 536,870,911, DEC2OCT
     *            returns the #NUM! error value.
     *            If number is nonnumeric, DEC2OCT returns the #VALUE! error value.
     *            If DEC2OCT requires more than places characters, it returns the
     *            #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, DEC2OCT uses
     *            the minimum number of characters necessary. Places is useful for
     *            padding the return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, DEC2OCT returns the #VALUE! error value.
     *            If places is zero or negative, DEC2OCT returns the #NUM! error value.
     * @return string
     */
    public static function DECTOOCT($x, $places = null) {
        $xorig = $x;
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            if (Functions::getCompatibilityMode() == Functions::COMPATIBILITY_OPENOFFICE) {
                $x = (int) $x;
            } else {
                return Functions::VALUE();
            }
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[-0123456789.]/', $x, $out)) {
            return Functions::VALUE();
        }
        $x = (string) floor($x);
        $r = decoct($x);
        if (strlen($r) == 11) {
            // Two's Complement
            $r = substr($r, -10);
        }
        
        return self::nbrConversionFormat($r, $places);
    }
    
    /**
     * HEXTOBIN
     *
     * Return a hex value as binary.
     *
     * Excel Function:
     * HEX2BIN(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            the hexadecimal number you want to convert.
     *            Number cannot contain more than 10 characters.
     *            The most significant bit of number is the sign bit (40th bit from the right).
     *            The remaining 9 bits are magnitude bits.
     *            Negative numbers are represented using two's-complement notation.
     *            If number is negative, HEX2BIN ignores places and returns a 10-character binary number.
     *            If number is negative, it cannot be less than FFFFFFFE00,
     *            and if number is positive, it cannot be greater than 1FF.
     *            If number is not a valid hexadecimal number, HEX2BIN returns the #NUM! error value.
     *            If HEX2BIN requires more than places characters, it returns the #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted,
     *            HEX2BIN uses the minimum number of characters necessary. Places
     *            is useful for padding the return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, HEX2BIN returns the #VALUE! error value.
     *            If places is negative, HEX2BIN returns the #NUM! error value.
     * @return string
     */
    public static function HEXTOBIN($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            return Functions::VALUE();
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[0123456789ABCDEF]/', strtoupper($x), $out)) {
            return Functions::NAN();
        }
        if (hexdec($x) > 0x1FF) {
            return Functions::NAN();
        }
        $binVal = decbin(hexdec($x));
        return substr(self::nbrConversionFormat($binVal, $places), -10);
    }
    
    /**
     * HEXTODEC
     *
     * Return a hex value as decimal.
     *
     * Excel Function:
     * HEX2DEC(x)
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The hexadecimal number you want to convert. This number cannot
     *            contain more than 10 characters (40 bits). The most significant
     *            bit of number is the sign bit. The remaining 39 bits are magnitude
     *            bits. Negative numbers are represented using two's-complement
     *            notation.
     *            If number is not a valid hexadecimal number, HEX2DEC returns the
     *            #NUM! error value.
     * @return string
     */
    public static function HEXTODEC($x) {
        $x = Functions::flattenSingleValue($x);
        
        if (is_bool($x)) {
            return Functions::VALUE();
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[0123456789ABCDEF]/', strtoupper($x), $out)) {
            return Functions::NAN();
        }
        $binX = '';
        foreach ( str_split($x) as $char ) {
            $binX .= str_pad(base_convert($char, 16, 2), 3, '0', STR_PAD_LEFT);
        }
        if (strlen($binX) == 40 && $binX[0] == '1') {
            for($i = 0; $i < 40; $i++) {
                $binX[$i] = ($binX[$i] == '1' ? '0' : '1');
            }
            return (bindec($binX) + 1) * -1;
        }
        return bindec($binX);
    }
    
    /**
     * HEXTOOCT
     *
     * Return a hex value as octal.
     *
     * Excel Function:
     * HEX2OCT(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The hexadecimal number you want to convert. Number cannot
     *            contain more than 10 characters. The most significant bit of
     *            number is the sign bit. The remaining 39 bits are magnitude
     *            bits. Negative numbers are represented using two's-complement
     *            notation.
     *            If number is negative, HEX2OCT ignores places and returns a
     *            10-character octal number.
     *            If number is negative, it cannot be less than FFE0000000, and
     *            if number is positive, it cannot be greater than 1FFFFFFF.
     *            If number is not a valid hexadecimal number, HEX2OCT returns
     *            the #NUM! error value.
     *            If HEX2OCT requires more than places characters, it returns
     *            the #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, HEX2OCT
     *            uses the minimum number of characters necessary. Places is
     *            useful for padding the return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, HEX2OCT returns the #VALUE! error
     *            value.
     *            If places is negative, HEX2OCT returns the #NUM! error value.
     * @return string
     */
    public static function HEXTOOCT($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            return Functions::VALUE();
        }
        $x = (string) $x;
        if (strlen($x) > preg_match_all('/[0123456789ABCDEF]/', strtoupper($x), $out)) {
            return Functions::NAN();
        }
        $octVal = decoct(hexdec($x));
        
        return self::nbrConversionFormat($octVal, $places);
    }
    
    /**
     * OCTTOBIN
     *
     * Return an octal value as binary.
     *
     * Excel Function:
     * OCT2BIN(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The octal number you want to convert. Number may not
     *            contain more than 10 characters. The most significant
     *            bit of number is the sign bit. The remaining 29 bits
     *            are magnitude bits. Negative numbers are represented
     *            using two's-complement notation.
     *            If number is negative, OCT2BIN ignores places and returns
     *            a 10-character binary number.
     *            If number is negative, it cannot be less than 7777777000,
     *            and if number is positive, it cannot be greater than 777.
     *            If number is not a valid octal number, OCT2BIN returns
     *            the #NUM! error value.
     *            If OCT2BIN requires more than places characters, it
     *            returns the #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted,
     *            OCT2BIN uses the minimum number of characters necessary.
     *            Places is useful for padding the return value with
     *            leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, OCT2BIN returns the #VALUE!
     *            error value.
     *            If places is negative, OCT2BIN returns the #NUM! error
     *            value.
     * @return string
     */
    public static function OCTTOBIN($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            return Functions::VALUE();
        }
        $x = (string) $x;
        if (preg_match_all('/[01234567]/', $x, $out) != strlen($x)) {
            return Functions::NAN();
        }
        $r = decbin(octdec($x));
        
        return self::nbrConversionFormat($r, $places);
    }
    
    /**
     * OCTTODEC
     *
     * Return an octal value as decimal.
     *
     * Excel Function:
     * OCT2DEC(x)
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The octal number you want to convert. Number may not contain
     *            more than 10 octal characters (30 bits). The most significant
     *            bit of number is the sign bit. The remaining 29 bits are
     *            magnitude bits. Negative numbers are represented using
     *            two's-complement notation.
     *            If number is not a valid octal number, OCT2DEC returns the
     *            #NUM! error value.
     * @return string
     */
    public static function OCTTODEC($x) {
        $x = Functions::flattenSingleValue($x);
        
        if (is_bool($x)) {
            return Functions::VALUE();
        }
        $x = (string) $x;
        if (preg_match_all('/[01234567]/', $x, $out) != strlen($x)) {
            return Functions::NAN();
        }
        $binX = '';
        foreach ( str_split($x) as $char ) {
            $binX .= str_pad(decbin((int) $char), 3, '0', STR_PAD_LEFT);
        }
        if (strlen($binX) == 30 && $binX[0] == '1') {
            for($i = 0; $i < 30; $i++) {
                $binX[$i] = ($binX[$i] == '1' ? '0' : '1');
            }
            return (bindec($binX) + 1) * -1;
        }
        return bindec($binX);
    }
    
    /**
     * OCTTOHEX
     *
     * Return an octal value as hex.
     *
     * Excel Function:
     * OCT2HEX(x[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param string $x
     *            The octal number you want to convert. Number may not contain
     *            more than 10 octal characters (30 bits). The most significant
     *            bit of number is the sign bit. The remaining 29 bits are
     *            magnitude bits. Negative numbers are represented using
     *            two's-complement notation.
     *            If number is negative, OCT2HEX ignores places and returns a
     *            10-character hexadecimal number.
     *            If number is not a valid octal number, OCT2HEX returns the
     *            #NUM! error value.
     *            If OCT2HEX requires more than places characters, it returns
     *            the #NUM! error value.
     * @param integer $places
     *            The number of characters to use. If places is omitted, OCT2HEX
     *            uses the minimum number of characters necessary. Places is useful
     *            for padding the return value with leading 0s (zeros).
     *            If places is not an integer, it is truncated.
     *            If places is nonnumeric, OCT2HEX returns the #VALUE! error value.
     *            If places is negative, OCT2HEX returns the #NUM! error value.
     * @return string
     */
    public static function OCTTOHEX($x, $places = null) {
        $x = Functions::flattenSingleValue($x);
        $places = Functions::flattenSingleValue($places);
        
        if (is_bool($x)) {
            return Functions::VALUE();
        }
        $x = (string) $x;
        if (preg_match_all('/[01234567]/', $x, $out) != strlen($x)) {
            return Functions::NAN();
        }
        $hexVal = strtoupper(dechex(self::OCTTODEC($x)));
        
        return self::nbrConversionFormat($hexVal, $places);
    }
    
    /**
     * COMPLEX
     *
     * Converts real and imaginary coefficients into a complex number of the form x + yi or x + yj.
     *
     * Excel Function:
     * COMPLEX(realNumber,imaginary[,places])
     *
     * @access public
     * @category Engineering Functions
     * @param float $realNumber
     *            The real coefficient of the complex number.
     * @param float $imaginary
     *            The imaginary coefficient of the complex number.
     * @param string $suffix
     *            The suffix for the imaginary component of the complex number.
     *            If omitted, the suffix is assumed to be "i".
     * @return string
     */
    public static function COMPLEX($realNumber = 0.0, $imaginary = 0.0, $suffix = 'i') {
        $realNumber = (is_null($realNumber)) ? 0.0 : Functions::flattenSingleValue($realNumber);
        $imaginary = (is_null($imaginary)) ? 0.0 : Functions::flattenSingleValue($imaginary);
        $suffix = (is_null($suffix)) ? 'i' : Functions::flattenSingleValue($suffix);
        
        if (((is_numeric($realNumber)) && (is_numeric($imaginary))) && (($suffix == 'i') || ($suffix == 'j') || ($suffix == ''))) {
            $realNumber = (float) $realNumber;
            $imaginary = (float) $imaginary;
            
            if ($suffix == '') {
                $suffix = 'i';
            }
            if ($realNumber == 0.0) {
                if ($imaginary == 0.0) {
                    return (string) '0';
                } elseif ($imaginary == 1.0) {
                    return (string) $suffix;
                } elseif ($imaginary == -1.0) {
                    return (string) '-' . $suffix;
                }
                return (string) $imaginary . $suffix;
            } elseif ($imaginary == 0.0) {
                return (string) $realNumber;
            } elseif ($imaginary == 1.0) {
                return (string) $realNumber . '+' . $suffix;
            } elseif ($imaginary == -1.0) {
                return (string) $realNumber . '-' . $suffix;
            }
            if ($imaginary > 0) {
                $imaginary = (string) '+' . $imaginary;
            }
            return (string) $realNumber . $imaginary . $suffix;
        }
        
        return Functions::VALUE();
    }
    
    /**
     * IMAGINARY
     *
     * Returns the imaginary coefficient of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMAGINARY(complexNumber)
     *
     * @access public
     * @category Engineering Functions
     * @param string $complexNumber
     *            The complex number for which you want the imaginary
     *            coefficient.
     * @return float
     */
    public static function IMAGINARY($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        return $parsedComplex['imaginary'];
    }
    
    /**
     * IMREAL
     *
     * Returns the real coefficient of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMREAL(complexNumber)
     *
     * @access public
     * @category Engineering Functions
     * @param string $complexNumber
     *            The complex number for which you want the real coefficient.
     * @return float
     */
    public static function IMREAL($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        return $parsedComplex['real'];
    }
    
    /**
     * IMABS
     *
     * Returns the absolute value (modulus) of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMABS(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the absolute value.
     * @return float
     */
    public static function IMABS($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        return sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary']));
    }
    
    /**
     * IMARGUMENT
     *
     * Returns the argument theta of a complex number, i.e. the angle in radians from the real
     * axis to the representation of the number in polar coordinates.
     *
     * Excel Function:
     * IMARGUMENT(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the argument theta.
     * @return float
     */
    public static function IMARGUMENT($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        $parsedComplex = self::parseComplex($complexNumber);
        if ($parsedComplex['real'] == 0.0) {
            if ($parsedComplex['imaginary'] == 0.0) {
                return Functions::DIV0();
            } elseif ($parsedComplex['imaginary'] < 0.0) {
                return M_PI / -2;
            } else {
                return M_PI / 2;
            }
        } elseif ($parsedComplex['real'] > 0.0) {
            return atan($parsedComplex['imaginary'] / $parsedComplex['real']);
        } elseif ($parsedComplex['imaginary'] < 0.0) {
            return 0 - (M_PI - atan(abs($parsedComplex['imaginary']) / abs($parsedComplex['real'])));
        } else {
            return M_PI - atan($parsedComplex['imaginary'] / abs($parsedComplex['real']));
        }
    }
    
    /**
     * IMCONJUGATE
     *
     * Returns the complex conjugate of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMCONJUGATE(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the conjugate.
     * @return string
     */
    public static function IMCONJUGATE($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if ($parsedComplex['imaginary'] == 0.0) {
            return $parsedComplex['real'];
        } else {
            return self::cleanComplex(self::COMPLEX($parsedComplex['real'], 0 - $parsedComplex['imaginary'], $parsedComplex['suffix']));
        }
    }
    
    /**
     * IMCOS
     *
     * Returns the cosine of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMCOS(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the cosine.
     * @return string|float
     */
    public static function IMCOS($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if ($parsedComplex['imaginary'] == 0.0) {
            return cos($parsedComplex['real']);
        } else {
            return self::IMCONJUGATE(self::COMPLEX(cos($parsedComplex['real']) * cosh($parsedComplex['imaginary']), sin($parsedComplex['real']) * sinh($parsedComplex['imaginary']), $parsedComplex['suffix']));
        }
    }
    
    /**
     * IMSIN
     *
     * Returns the sine of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMSIN(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the sine.
     * @return string|float
     */
    public static function IMSIN($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if ($parsedComplex['imaginary'] == 0.0) {
            return sin($parsedComplex['real']);
        } else {
            return self::COMPLEX(sin($parsedComplex['real']) * cosh($parsedComplex['imaginary']), cos($parsedComplex['real']) * sinh($parsedComplex['imaginary']), $parsedComplex['suffix']);
        }
    }
    
    /**
     * IMSQRT
     *
     * Returns the square root of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMSQRT(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the square root.
     * @return string
     */
    public static function IMSQRT($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        $theta = self::IMARGUMENT($complexNumber);
        $d1 = cos($theta / 2);
        $d2 = sin($theta / 2);
        $r = sqrt(sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary'])));
        
        if ($parsedComplex['suffix'] == '') {
            return self::COMPLEX($d1 * $r, $d2 * $r);
        } else {
            return self::COMPLEX($d1 * $r, $d2 * $r, $parsedComplex['suffix']);
        }
    }
    
    /**
     * IMLN
     *
     * Returns the natural logarithm of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMLN(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the natural logarithm.
     * @return string
     */
    public static function IMLN($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
            return Functions::NAN();
        }
        
        $logR = log(sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary'])));
        $t = self::IMARGUMENT($complexNumber);
        
        if ($parsedComplex['suffix'] == '') {
            return self::COMPLEX($logR, $t);
        } else {
            return self::COMPLEX($logR, $t, $parsedComplex['suffix']);
        }
    }
    
    /**
     * IMLOG10
     *
     * Returns the common logarithm (base 10) of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMLOG10(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the common logarithm.
     * @return string
     */
    public static function IMLOG10($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
            return Functions::NAN();
        } elseif (($parsedComplex['real'] > 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
            return log10($parsedComplex['real']);
        }
        
        return self::IMPRODUCT(log10(EULER), self::IMLN($complexNumber));
    }
    
    /**
     * IMLOG2
     *
     * Returns the base-2 logarithm of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMLOG2(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the base-2 logarithm.
     * @return string
     */
    public static function IMLOG2($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
            return Functions::NAN();
        } elseif (($parsedComplex['real'] > 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
            return log($parsedComplex['real'], 2);
        }
        
        return self::IMPRODUCT(log(EULER, 2), self::IMLN($complexNumber));
    }
    
    /**
     * IMEXP
     *
     * Returns the exponential of a complex number in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMEXP(complexNumber)
     *
     * @param string $complexNumber
     *            The complex number for which you want the exponential.
     * @return string
     */
    public static function IMEXP($complexNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        if (($parsedComplex['real'] == 0.0) && ($parsedComplex['imaginary'] == 0.0)) {
            return '1';
        }
        
        $e = exp($parsedComplex['real']);
        $eX = $e * cos($parsedComplex['imaginary']);
        $eY = $e * sin($parsedComplex['imaginary']);
        
        if ($parsedComplex['suffix'] == '') {
            return self::COMPLEX($eX, $eY);
        } else {
            return self::COMPLEX($eX, $eY, $parsedComplex['suffix']);
        }
    }
    
    /**
     * IMPOWER
     *
     * Returns a complex number in x + yi or x + yj text format raised to a power.
     *
     * Excel Function:
     * IMPOWER(complexNumber,realNumber)
     *
     * @param string $complexNumber
     *            The complex number you want to raise to a power.
     * @param float $realNumber
     *            The power to which you want to raise the complex number.
     * @return string
     */
    public static function IMPOWER($complexNumber, $realNumber) {
        $complexNumber = Functions::flattenSingleValue($complexNumber);
        $realNumber = Functions::flattenSingleValue($realNumber);
        
        if (!is_numeric($realNumber)) {
            return Functions::VALUE();
        }
        
        $parsedComplex = self::parseComplex($complexNumber);
        
        $r = sqrt(($parsedComplex['real'] * $parsedComplex['real']) + ($parsedComplex['imaginary'] * $parsedComplex['imaginary']));
        $rPower = pow($r, $realNumber);
        $theta = self::IMARGUMENT($complexNumber) * $realNumber;
        if ($theta == 0) {
            return 1;
        } elseif ($parsedComplex['imaginary'] == 0.0) {
            return self::COMPLEX($rPower * cos($theta), $rPower * sin($theta), $parsedComplex['suffix']);
        } else {
            return self::COMPLEX($rPower * cos($theta), $rPower * sin($theta), $parsedComplex['suffix']);
        }
    }
    
    /**
     * IMDIV
     *
     * Returns the quotient of two complex numbers in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMDIV(complexDividend,complexDivisor)
     *
     * @param string $complexDividend
     *            The complex numerator or dividend.
     * @param string $complexDivisor
     *            The complex denominator or divisor.
     * @return string
     */
    public static function IMDIV($complexDividend, $complexDivisor) {
        $complexDividend = Functions::flattenSingleValue($complexDividend);
        $complexDivisor = Functions::flattenSingleValue($complexDivisor);
        
        $parsedComplexDividend = self::parseComplex($complexDividend);
        $parsedComplexDivisor = self::parseComplex($complexDivisor);
        
        if (($parsedComplexDividend['suffix'] != '') && ($parsedComplexDivisor['suffix'] != '') && ($parsedComplexDividend['suffix'] != $parsedComplexDivisor['suffix'])) {
            return Functions::NAN();
        }
        if (($parsedComplexDividend['suffix'] != '') && ($parsedComplexDivisor['suffix'] == '')) {
            $parsedComplexDivisor['suffix'] = $parsedComplexDividend['suffix'];
        }
        
        $d1 = ($parsedComplexDividend['real'] * $parsedComplexDivisor['real']) + ($parsedComplexDividend['imaginary'] * $parsedComplexDivisor['imaginary']);
        $d2 = ($parsedComplexDividend['imaginary'] * $parsedComplexDivisor['real']) - ($parsedComplexDividend['real'] * $parsedComplexDivisor['imaginary']);
        $d3 = ($parsedComplexDivisor['real'] * $parsedComplexDivisor['real']) + ($parsedComplexDivisor['imaginary'] * $parsedComplexDivisor['imaginary']);
        
        $r = $d1 / $d3;
        $i = $d2 / $d3;
        
        if ($i > 0.0) {
            return self::cleanComplex($r . '+' . $i . $parsedComplexDivisor['suffix']);
        } elseif ($i < 0.0) {
            return self::cleanComplex($r . $i . $parsedComplexDivisor['suffix']);
        } else {
            return $r;
        }
    }
    
    /**
     * IMSUB
     *
     * Returns the difference of two complex numbers in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMSUB(complexNumber1,complexNumber2)
     *
     * @param string $complexNumber1
     *            The complex number from which to subtract complexNumber2.
     * @param string $complexNumber2
     *            The complex number to subtract from complexNumber1.
     * @return string
     */
    public static function IMSUB($complexNumber1, $complexNumber2) {
        $complexNumber1 = Functions::flattenSingleValue($complexNumber1);
        $complexNumber2 = Functions::flattenSingleValue($complexNumber2);
        
        $parsedComplex1 = self::parseComplex($complexNumber1);
        $parsedComplex2 = self::parseComplex($complexNumber2);
        
        if ((($parsedComplex1['suffix'] != '') && ($parsedComplex2['suffix'] != '')) && ($parsedComplex1['suffix'] != $parsedComplex2['suffix'])) {
            return Functions::NAN();
        } elseif (($parsedComplex1['suffix'] == '') && ($parsedComplex2['suffix'] != '')) {
            $parsedComplex1['suffix'] = $parsedComplex2['suffix'];
        }
        
        $d1 = $parsedComplex1['real'] - $parsedComplex2['real'];
        $d2 = $parsedComplex1['imaginary'] - $parsedComplex2['imaginary'];
        
        return self::COMPLEX($d1, $d2, $parsedComplex1['suffix']);
    }
    
    /**
     * IMSUM
     *
     * Returns the sum of two or more complex numbers in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMSUM(complexNumber[,complexNumber[,...]])
     *
     * @param string $complexNumber,...
     *            Series of complex numbers to add
     * @return string
     */
    public static function IMSUM() {
        // Return value
        $returnValue = self::parseComplex('0');
        $activeSuffix = '';
        
        // Loop through the arguments
        $aArgs = Functions::flattenArray(func_get_args());
        foreach ( $aArgs as $arg ) {
            $parsedComplex = self::parseComplex($arg);
            
            if ($activeSuffix == '') {
                $activeSuffix = $parsedComplex['suffix'];
            } elseif (($parsedComplex['suffix'] != '') && ($activeSuffix != $parsedComplex['suffix'])) {
                return Functions::NAN();
            }
            
            $returnValue['real'] += $parsedComplex['real'];
            $returnValue['imaginary'] += $parsedComplex['imaginary'];
        }
        
        if ($returnValue['imaginary'] == 0.0) {
            $activeSuffix = '';
        }
        return self::COMPLEX($returnValue['real'], $returnValue['imaginary'], $activeSuffix);
    }
    
    /**
     * IMPRODUCT
     *
     * Returns the product of two or more complex numbers in x + yi or x + yj text format.
     *
     * Excel Function:
     * IMPRODUCT(complexNumber[,complexNumber[,...]])
     *
     * @param string $complexNumber,...
     *            Series of complex numbers to multiply
     * @return string
     */
    public static function IMPRODUCT() {
        // Return value
        $returnValue = self::parseComplex('1');
        $activeSuffix = '';
        
        // Loop through the arguments
        $aArgs = Functions::flattenArray(func_get_args());
        foreach ( $aArgs as $arg ) {
            $parsedComplex = self::parseComplex($arg);
            
            $workValue = $returnValue;
            if (($parsedComplex['suffix'] != '') && ($activeSuffix == '')) {
                $activeSuffix = $parsedComplex['suffix'];
            } elseif (($parsedComplex['suffix'] != '') && ($activeSuffix != $parsedComplex['suffix'])) {
                return Functions::NAN();
            }
            $returnValue['real'] = ($workValue['real'] * $parsedComplex['real']) - ($workValue['imaginary'] * $parsedComplex['imaginary']);
            $returnValue['imaginary'] = ($workValue['real'] * $parsedComplex['imaginary']) + ($workValue['imaginary'] * $parsedComplex['real']);
        }
        
        if ($returnValue['imaginary'] == 0.0) {
            $activeSuffix = '';
        }
        return self::COMPLEX($returnValue['real'], $returnValue['imaginary'], $activeSuffix);
    }
    
    /**
     * DELTA
     *
     * Tests whether two values are equal. Returns 1 if number1 = number2; returns 0 otherwise.
     * Use this function to filter a set of values. For example, by summing several DELTA
     * functions you calculate the count of equal pairs. This function is also known as the
     * Kronecker Delta function.
     *
     * Excel Function:
     * DELTA(a[,b])
     *
     * @param float $a
     *            The first number.
     * @param float $b
     *            The second number. If omitted, b is assumed to be zero.
     * @return int
     */
    public static function DELTA($a, $b = 0) {
        $a = Functions::flattenSingleValue($a);
        $b = Functions::flattenSingleValue($b);
        
        return (int) ($a == $b);
    }
    
    /**
     * GESTEP
     *
     * Excel Function:
     * GESTEP(number[,step])
     *
     * Returns 1 if number >= step; returns 0 (zero) otherwise
     * Use this function to filter a set of values. For example, by summing several GESTEP
     * functions you calculate the count of values that exceed a threshold.
     *
     * @param float $number
     *            The value to test against step.
     * @param float $step
     *            The threshold value.
     *            If you omit a value for step, GESTEP uses zero.
     * @return int
     */
    public static function GESTEP($number, $step = 0) {
        $number = Functions::flattenSingleValue($number);
        $step = Functions::flattenSingleValue($step);
        
        return (int) ($number >= $step);
    }
    
    //
    // Private method to calculate the erf value
    //
    private static $twoSqrtPi = 1.128379167095512574;
    public static function erfVal($x) {
        if (abs($x) > 2.2) {
            return 1 - self::erfcVal($x);
        }
        $sum = $term = $x;
        $xsqr = ($x * $x);
        $j = 1;
        do {
            $term *= $xsqr / $j;
            $sum -= $term / (2 * $j + 1);
            ++$j;
            $term *= $xsqr / $j;
            $sum += $term / (2 * $j + 1);
            ++$j;
            if ($sum == 0.0) {
                break;
            }
        } while ( abs($term / $sum) > PRECISION );
        return self::$twoSqrtPi * $sum;
    }
    
    /**
     * ERF
     *
     * Returns the error function integrated between the lower and upper bound arguments.
     *
     * Note: In Excel 2007 or earlier, if you input a negative value for the upper or lower bound arguments,
     * the function would return a #NUM! error. However, in Excel 2010, the function algorithm was
     * improved, so that it can now calculate the function for both positive and negative ranges.
     * PHPExcel follows Excel 2010 behaviour, and accepts nagative arguments.
     *
     * Excel Function:
     * ERF(lower[,upper])
     *
     * @param float $lower
     *            lower bound for integrating ERF
     * @param float $upper
     *            upper bound for integrating ERF.
     *            If omitted, ERF integrates between zero and lower_limit
     * @return float
     */
    public static function ERF($lower, $upper = null) {
        $lower = Functions::flattenSingleValue($lower);
        $upper = Functions::flattenSingleValue($upper);
        
        if (is_numeric($lower)) {
            if (is_null($upper)) {
                return self::erfVal($lower);
            }
            if (is_numeric($upper)) {
                return self::erfVal($upper) - self::erfVal($lower);
            }
        }
        return Functions::VALUE();
    }
    
    //
    // Private method to calculate the erfc value
    //
    private static $oneSqrtPi = 0.564189583547756287;
    private static function erfcVal($x) {
        if (abs($x) < 2.2) {
            return 1 - self::erfVal($x);
        }
        if ($x < 0) {
            return 2 - self::ERFC(-$x);
        }
        $a = $n = 1;
        $b = $c = $x;
        $d = ($x * $x) + 0.5;
        $q1 = $q2 = $b / $d;
        $t = 0;
        do {
            $t = $a * $n + $b * $x;
            $a = $b;
            $b = $t;
            $t = $c * $n + $d * $x;
            $c = $d;
            $d = $t;
            $n += 0.5;
            $q1 = $q2;
            $q2 = $b / $d;
        } while ( (abs($q1 - $q2) / $q2) > PRECISION );
        return self::$oneSqrtPi * exp(-$x * $x) * $q2;
    }
    
    /**
     * ERFC
     *
     * Returns the complementary ERF function integrated between x and infinity
     *
     * Note: In Excel 2007 or earlier, if you input a negative value for the lower bound argument,
     * the function would return a #NUM! error. However, in Excel 2010, the function algorithm was
     * improved, so that it can now calculate the function for both positive and negative x values.
     * PHPExcel follows Excel 2010 behaviour, and accepts nagative arguments.
     *
     * Excel Function:
     * ERFC(x)
     *
     * @param float $x
     *            The lower bound for integrating ERFC
     * @return float
     */
    public static function ERFC($x) {
        $x = Functions::flattenSingleValue($x);
        
        if (is_numeric($x)) {
            return self::erfcVal($x);
        }
        return Functions::VALUE();
    }
    
    /**
     * getConversionGroups
     * Returns a list of the different conversion groups for UOM conversions
     *
     * @return array
     */
    public static function getConversionGroups() {
        $conversionGroups = array();
        foreach ( self::$conversionUnits as $conversionUnit ) {
            $conversionGroups[] = $conversionUnit['Group'];
        }
        return array_merge(array_unique($conversionGroups));
    }
    
    /**
     * getConversionGroupUnits
     * Returns an array of units of measure, for a specified conversion group, or for all groups
     *
     * @param string $group
     *            The group whose units of measure you want to retrieve
     * @return array
     */
    public static function getConversionGroupUnits($group = null) {
        $conversionGroups = array();
        foreach ( self::$conversionUnits as $conversionUnit => $conversionGroup ) {
            if ((is_null($group)) || ($conversionGroup['Group'] == $group)) {
                $conversionGroups[$conversionGroup['Group']][] = $conversionUnit;
            }
        }
        return $conversionGroups;
    }
    
    /**
     * getConversionGroupUnitDetails
     *
     * @param string $group
     *            The group whose units of measure you want to retrieve
     * @return array
     */
    public static function getConversionGroupUnitDetails($group = null) {
        $conversionGroups = array();
        foreach ( self::$conversionUnits as $conversionUnit => $conversionGroup ) {
            if ((is_null($group)) || ($conversionGroup['Group'] == $group)) {
                $conversionGroups[$conversionGroup['Group']][] = array(
                'unit' => $conversionUnit,
                'description' => $conversionGroup['Unit Name'] 
                );
            }
        }
        return $conversionGroups;
    }
    
    /**
     * getConversionMultipliers
     * Returns an array of the Multiplier prefixes that can be used with Units of Measure in CONVERTUOM()
     *
     * @return array of mixed
     */
    public static function getConversionMultipliers() {
        return self::$conversionMultipliers;
    }
    
    /**
     * CONVERTUOM
     *
     * Converts a number from one measurement system to another.
     * For example, CONVERT can translate a table of distances in miles to a table of distances
     * in kilometers.
     *
     * Excel Function:
     * CONVERT(value,fromUOM,toUOM)
     *
     * @param float $value
     *            The value in fromUOM to convert.
     * @param string $fromUOM
     *            The units for value.
     * @param string $toUOM
     *            The units for the result.
     *            
     * @return float
     */
    public static function CONVERTUOM($value, $fromUOM, $toUOM) {
        $value = Functions::flattenSingleValue($value);
        $fromUOM = Functions::flattenSingleValue($fromUOM);
        $toUOM = Functions::flattenSingleValue($toUOM);
        
        if (!is_numeric($value)) {
            return Functions::VALUE();
        }
        $fromMultiplier = 1.0;
        if (isset(self::$conversionUnits[$fromUOM])) {
            $unitGroup1 = self::$conversionUnits[$fromUOM]['Group'];
        } else {
            $fromMultiplier = substr($fromUOM, 0, 1);
            $fromUOM = substr($fromUOM, 1);
            if (isset(self::$conversionMultipliers[$fromMultiplier])) {
                $fromMultiplier = self::$conversionMultipliers[$fromMultiplier]['multiplier'];
            } else {
                return Functions::NA();
            }
            if ((isset(self::$conversionUnits[$fromUOM])) && (self::$conversionUnits[$fromUOM]['AllowPrefix'])) {
                $unitGroup1 = self::$conversionUnits[$fromUOM]['Group'];
            } else {
                return Functions::NA();
            }
        }
        $value *= $fromMultiplier;
        
        $toMultiplier = 1.0;
        if (isset(self::$conversionUnits[$toUOM])) {
            $unitGroup2 = self::$conversionUnits[$toUOM]['Group'];
        } else {
            $toMultiplier = substr($toUOM, 0, 1);
            $toUOM = substr($toUOM, 1);
            if (isset(self::$conversionMultipliers[$toMultiplier])) {
                $toMultiplier = self::$conversionMultipliers[$toMultiplier]['multiplier'];
            } else {
                return Functions::NA();
            }
            if ((isset(self::$conversionUnits[$toUOM])) && (self::$conversionUnits[$toUOM]['AllowPrefix'])) {
                $unitGroup2 = self::$conversionUnits[$toUOM]['Group'];
            } else {
                return Functions::NA();
            }
        }
        if ($unitGroup1 != $unitGroup2) {
            return Functions::NA();
        }
        
        if (($fromUOM == $toUOM) && ($fromMultiplier == $toMultiplier)) {
            // We've already factored $fromMultiplier into the value, so we need
            // to reverse it again
            return $value / $fromMultiplier;
        } elseif ($unitGroup1 == 'Temperature') {
            if (($fromUOM == 'F') || ($fromUOM == 'fah')) {
                if (($toUOM == 'F') || ($toUOM == 'fah')) {
                    return $value;
                } else {
                    $value = (($value - 32) / 1.8);
                    if (($toUOM == 'K') || ($toUOM == 'kel')) {
                        $value += 273.15;
                    }
                    return $value;
                }
            } elseif ((($fromUOM == 'K') || ($fromUOM == 'kel')) && (($toUOM == 'K') || ($toUOM == 'kel'))) {
                return $value;
            } elseif ((($fromUOM == 'C') || ($fromUOM == 'cel')) && (($toUOM == 'C') || ($toUOM == 'cel'))) {
                return $value;
            }
            if (($toUOM == 'F') || ($toUOM == 'fah')) {
                if (($fromUOM == 'K') || ($fromUOM == 'kel')) {
                    $value -= 273.15;
                }
                return ($value * 1.8) + 32;
            }
            if (($toUOM == 'C') || ($toUOM == 'cel')) {
                return $value - 273.15;
            }
            return $value + 273.15;
        }
        return ($value * self::$unitConversions[$unitGroup1][$fromUOM][$toUOM]) / $toMultiplier;
    }
}
